Prenatal use of medications by women giving birth at a university hospital.

Medication use during pregnancy has changed over time because of various factors: new products have been marketed, concerns have arisen regarding safety and efficacy, public education has increased, and some prescription medications have been granted nonprescription status by the Food and Drug Administration. The purpose of this investigation was to determine overall medication and substance use by prenatal patients whose infants were delivered at our tertiary university hospital. Within 96 hours after delivery, 100 women were evaluated by a personal interview and medical record review. The medications most commonly used during pregnancy were vitamins, analgesics, calcium and iron preparations, and antibiotics. The mean numbers of medications consumed during the second and third trimesters (3.32 +/- 1.87 and 4.13 +/- 2.46) were significantly higher than the mean number taken before pregnancy (2.65 +/- 1.95). Over-the-counter medications accounted for 54% of the total products taken during pregnancy. Percentages of women using caffeine, tobacco, alcohol, and illicit drugs decreased during pregnancy.

Effect of pH on the equilibrium dialysis of phenytoin suspension with and without enteral feeding formula.

Significant decreases have been reported in phenytoin absorption when the suspension is combined with continuous enteral feedings. Several theories for this interaction have been proposed including binding of phenytoin to the protein constituents of the enteral formula, phenytoin binding to the calcium in the enteral formula, and inadequate dissolution of the suspension when delivered with the enteral formula due to the high pKa of phenytoin and the acidic nature of the enteral formula. We therefore evaluated the effects of pH levels 2.0, 3.5, 6.0, and 8.0 on the interaction of phenytoin suspension with enteral formula (Osmolite) with equilibrium dialysis using a Spectra/Por 1 (MWCO 6000-8000) molecularporous dialysis membrane. Phenytoin concentrations in the dialysis membrane (internal phase) mimicked the expected stomach concentrations of a 100-mg dose administered in an adult stomach containing 200 ml of gastric fluid. External phase buffers were sampled at 0.5, 1.0, 2.0, 4.0, 8.0, 12.0, and 24.0 hr after the start of the dialysis. The phenytoin concentrations in the external phase were compared between buffer alone or buffer combined with enteral formula at the same pH and time intervals. With pH 2.0 and 3.5 the enteral formula formed an aggregate with suspension whereas no aggregate was formed with pH 6.0 and 8.0. The phenytoin concentrations with pH 2.0 were 26% to 44% lower and with pH 3.5 were 11.5 to 27% lower when phenytoin suspension was combined with enteral solution. However, at 24 hr there was no difference between the two conditions with both pH 2.0 and 3.5.(ABSTRACT TRUNCATED AT 250 WORDS)

Recovery of phenytoin suspension after in vitro administration through percutaneous endoscopic gastrostomy Pezzer catheters.

Various methods of administering phenytoin suspension through a percutaneous endoscopic gastrostomy (PEG) Pezzer catheter were evaluated in vitro to determine which method resulted in the most complete recovery of phenytoin. To determine the effect of temperature on phenytoin recovery, 12 mL of phenytoin suspension (Dilantin-125, 125 mg/5 mL) was administered through three separate 35.5-cm 20 French latex PEG Pezzer catheters under each of three temperature conditions (suspension 11.8 degrees C and catheter 22 degrees C, suspension and catheter 22 degrees C, and suspension 22 degrees C and catheter 37 degrees C). To determine the effect of the administration method, 12-mL aliquots of phenytoin suspension were injected into the catheter by seven methods that varied with respect to catheter temperature, dilution of suspension, and irrigation of catheter. Each method was tested in triplicate, and samples were assayed by high-performance liquid chromatography. Varying the temperature of the catheter or suspension had little effect on the recovery of phenytoin. There was no appreciable loss of phenytoin when the suspension was undiluted, regardless of whether the catheter was irrigated. The greatest losses were seen when the suspension was diluted before administration. Irrigation also caused a decrease in recovery, but to a lesser extent than dilution. Until the effects of administering multiple doses of phenytoin through PEG Pezzer catheters are investigated, phenytoin suspension should not be diluted before administration because of decreased recovery and increased administration time.